CN112416041A

CN112416041A - Digital low dropout regulator, transistor anti-aging method and electronic equipment

Info

Publication number: CN112416041A
Application number: CN202011297770.9A
Authority: CN
Inventors: 吴春红; 金军贵
Original assignee: Haiguang Information Technology Co Ltd
Current assignee: Haiguang Information Technology Co Ltd
Priority date: 2020-11-18
Filing date: 2020-11-18
Publication date: 2021-02-26
Anticipated expiration: 2040-11-18
Also published as: CN112416041B

Abstract

The application relates to a digital low dropout regulator, a transistor anti-aging method and electronic equipment, and belongs to the technical field of electronics. The voltage stabilizer includes: the circuit comprises a transistor array, a first controller and an extended circulation unit; the first controller is used for generating a loop control signal; the extended cyclic unit is used for extending the input K bit signal (the K bit to 1 bit signal in the loop control signal) into the signal with i bit effective bits and 2^K1 transistors one to one 2^K-1-bit logic signal, 2 corresponding to the previous and the next time^K-at least one of the i-bit significant bits in the 1-bit logic signal is located differently such that it is turned on at a previous time and at a subsequent timeThe transistors are different. By expanding the input K-bit signal to 2^KLogic signal of 1 bit, so that the conducting transistor is no longer fixed, can be at 2^K-1, switching in the transistor, thereby preventing the transistor from working for a long time to accelerate aging and prolonging the service life.

Description

Digital low dropout regulator, transistor anti-aging method and electronic equipment

Technical Field

The application belongs to the technical field of electronics, and particularly relates to a digital low dropout regulator, a transistor anti-aging method and electronic equipment.

Background

A Digital Low Dropout regulatOr (DLDO) is a Digital Direct Current (DC) linear regulatOr that can provide configurable current and configurable voltage for different loads (loading). The large transistors of DLDO are typically constructed from several groups of identical transistor arrays (clone arrays). Each group of transistor arrays may be divided into different sub-groups according to weights, the Most weighted being called the Most Significant Bit (MSB) and the Least weighted being called the Least Significant Bit (LSB). When the load of the DLDO is in an idle state (idle) or a low power consumption mode, the required current is very small, so that only a few bits (e.g. 3 bits) in the Loop control signal (Loop data in [ N:1], N is a positive integer) output by the DLDO controller are changed, and only a few transistors with smaller weights are turned on to provide smaller current. The few transistors of lesser weight are always active, while the other transistors are inactive when the load is in an idle state or low power mode. In the long run, these transistors, which have been in operation, age more quickly and have a reduced lifetime.

Disclosure of Invention

In view of the above, an objective of the present application is to provide a digital low dropout regulator, a transistor aging prevention method and an electronic device, so as to solve the problem that some transistors in the conventional digital low dropout regulator are prone to aging.

The embodiment of the application is realized as follows:

in a first aspect, an embodiment of the present application provides a digital low dropout regulator, including: the device comprises a transistor array, a first controller and an extended circulation unit; the first controller is used for generating a loop control signal, the bit width of the loop control signal is N, and N is a positive integer; the input end of the extended circulation unit is used for receiving signals from the Kth bit to the 1 st bit in the loop control signals, and the output end of the extended circulation unit and the 2 corresponding to the K bit signals in the transistor array^K-1 transistor connection, K being a positive integer and less than N; the extension cycle unit for extending an input K-bit signal to have i-bit valid bits,and is in contact with said 2^K1 transistors one to one 2^K-1 bit logic signal, i is greater than or equal to 0 and less than or equal to 2^K-an integer of 1; wherein i is the number of transistors which can be respectively conducted by the K bit signal and the logic signal at present, and 2 corresponding to the previous moment^K-2 of the i-bit significant bits of the 1-bit logic signal corresponding to the subsequent time instant^KAt least one of the i-bit active bits in the 1-bit logic signal is located differently such that the transistors turned on at a previous time are different from those turned on at a subsequent time.

In the embodiment of the application, an input K bit signal is expanded into 2 with i bit effective bits through an expansion circulation unit^K-1-bit logic signal, such that one bit in the logic signal corresponds to only 2^KOne transistor of 1 transistor and the corresponding transistor of different bits in the logic signal is different, so that 2^K1 transistor can be controlled individually, while 2 corresponds to the previous moment^K-2 of the i-bit significant bits of the 1-bit logic signal corresponding to the subsequent time instant^K-at least one of the i-bit active bits in the 1-bit logic signal is located differently such that the conducting transistor is no longer fixed and can be at 2^K-1, switching in the transistor, thereby preventing the transistor from working for a long time to accelerate aging and prolonging the service life.

With reference to one possible implementation manner of the embodiment of the first aspect, the digital low dropout regulator further includes: the output end of the extended cycle unit is connected with the input end of the selector, and the first output end of the selector is connected with 2 corresponding to the K bit signal^K-1 transistor connection, the second output of the selector corresponding to 2 of the y-th bit in the loop control signal ^y-12 of one transistor^K-1 transistor connection, the control terminal of the selector being connected to a selection signal, y being an integer greater than or equal to K +1 and less than or equal to N; the selector is used for selecting the 2 according to the selection signal^K-1-bit logic signal is 2 for controlling said K-bit signal^K-1 transistor or 2 for the y-th bit^K-1 transistor.

In the embodiment of the application, the high order ([ N: K + 1) of the slave loop control signal is passed]) To select 2 corresponding to the y-th bit ^y-12 of one transistor ^K1 transistor 2 corresponding to K bit signal^K-1 transistor to form a candidate for a selector such that when the load of the DLDO is in idle state or low power mode, the turned on transistor is off except for the 2 corresponding to the

K bit signal

^K1, and 2 corresponding to the y bit^K-1 transistor cycle, which further relieves the corresponding 2 of the K bit signal^K-the aging rate of 1 transistor.

With reference to one possible implementation manner of the embodiment of the first aspect, the digital low dropout regulator further includes: the selector comprises N-K +1 output ends, the output end of the extended circulation unit is connected with the input end of the selector, the control end of the selector is connected with a selection signal, and the first output end of the selector corresponds to 2 corresponding to the K bit signal^K-1 transistor connection, the remaining N-K output terminals of the selector are respectively connected with 2 of the transistors respectively corresponding to the K +1 th bit to the N th bit in the loop control signal^K-1 transistor connection; the selector is used for selecting the 2 according to the selection signal^K-a set of target transistors controlled by a 1-bit logic signal, said set of target transistors being N-K +1 and 2^K-any one of a group of 1 transistors, wherein the bit width of the selection signal is N-K +1, each bit controlling one group of transistors.

In the embodiment of the application, the control signal [ N: K + 1] is controlled by the slave loop]One transistor group (2) is taken out from each bit-controlled transistor in the circuit^K-1) to form a candidate set of transistors for the selector together with the set of transistors corresponding to the K-bit signal to increase the number of selectors to select, thereby further mitigating the aging rate of the individual transistors.

With reference to one possible implementation manner of the embodiment of the first aspect, the extension cycle unit includes: a thermometer decoder having an input for receiving the Kth to 1 st signals of the loop control signalThe output end of the thermometer decoder is connected with a cyclic code circuit, and the thermometer decoder is used for decoding the input K bit signal into 2 with i bit effective bits^K-a 1-bit logic signal; the cyclic code circuit corresponds to 2 of the transistor array corresponding to the K-bit signal^K-1 transistor connection, said cyclic code circuit for adjusting said 2 in a specific order^K-the position of the i-bit valid bit in the 1-bit logic signal. In the embodiment of the application, a hardware mode combining a thermometer decoder and a cyclic code circuit is adopted to periodically adjust 2^K-the position of the i-bit valid bit in the 1-bit logic signal, such that the conducting transistor can be at 2^K-1 transistors, making the time of each conducting transistor as equal as possible.

With reference to one possible implementation manner of the embodiment of the first aspect, the cyclic code circuit includes: 2^K-1 and gates, said 2^K-1 bit logic signal and said 2^K-1 and gates in one-to-one correspondence; for each AND gate, the first input terminal of the AND gate is connected to the 2^K-a corresponding bit of the 1-bit logic signal is connected, a second input terminal of the and gate is externally connected with a setting signal, and an output terminal of the and gate is connected with a corresponding flip-flop; and said 2^K1 AND gates one to one 2^K-1 flip-flop, said 2^K-1 flip-flop with said 2^K-1 transistor to one; 2 is described^K-1 flip-flops are connected in series to form a flip-flop chain; the input end of the trigger positioned at the head end of the trigger chain is also connected with the output end of the trigger positioned at the tail end of the trigger chain; for each trigger, the setting end of the trigger is connected with the output end of the corresponding AND gate, the reset end of the trigger is grounded, and the output end of the trigger is also connected with the corresponding transistor.

In the embodiment of the application, a cyclic code circuit combining a trigger + an AND gate is adopted to periodically adjust 2^KThe position of the i-bit valid bit in the 1-bit logic signal has the advantages of simple circuit and convenient implementation.

With reference to one possible implementation manner of the embodiment of the first aspect, the following description is providedThe extended cyclic unit includes: a thermometer decoder, an input end of the thermometer decoder is used for receiving K bit to 1 bit signals in the loop control signals, an output end of the thermometer decoder is connected with the random number generator, and the thermometer decoder is used for decoding the input K bit signals into 2 bits with i bit significant bits^K-a 1-bit logic signal; the random number generator is 2 corresponding to the K bit signal in the transistor array^K-1 transistor connection, said random number generator for periodically randomly adjusting said 2^K-the position of the i-bit valid bit in the 1-bit logic signal.

In the embodiment of the application, a hardware mode combining a thermometer decoder and a random number generator is adopted, and the random number generator is periodically and randomly adjusted by 2^K-the position of the i-bit valid bit in the 1-bit logic signal, such that the conducting transistor can be at 2^KAnd (2) 1 transistor is switched, so that the scheme is enriched and the selectivity of the scheme is increased.

With reference to one possible implementation manner of the embodiment of the first aspect, the extension cycle unit is a second controller solidified with a specific program; the specific program is used for determining the number i of transistors which can be switched on currently according to the input K bit signal when being operated by the second controller; and expanding the input K bit signal into 2 with i bit effective bit according to the transistor conducting number i^K-a 1-bit logic signal; and also for periodically or randomly adjusting said 2^K-the position of the i-bit active bit in the 1-bit logic signal such that the transistors turned on at the previous time are different from those turned on at the next time.

In the embodiment of the application, the input K bit signal is expanded into 2 with i bit effective bits in a software mode^KA 1-bit logic signal, which can simplify the circuit area.

In a second aspect, an embodiment of the present application provides a transistor anti-aging method, which is applied to a digital low dropout regulator, where the digital low dropout regulator includes: the device comprises a transistor array, a first controller and a second controller; the first controller is used for generating a loop control signal, and the loop control signal is used for controlling the loopThe bit width of the control signal is N, and N is a positive integer; the input end of the second controller is used for receiving signals from the Kth bit to the 1 st bit in the loop control signals, K is a positive integer and is less than N, and the output end of the second controller and the 2 nd bit corresponding to the K bit signals in the transistor array^K-1 transistor connection; the method comprises the following steps: the second controller determines the number i of transistors which can be switched on currently by the K bit signal according to the input K bit signal, wherein i is more than or equal to 0 and less than or equal to 2^K-an integer of 1; the second controller expands the input K bit signal into 2 with i bit valid bit according to the transistor conducting number i^K-a 1-bit logic signal, wherein said 2^K-1 bit logic signal and said 2^K-1 transistor to one; the second controller adjusts the 2 periodically or randomly^K-the position of the i-bit active bit in the 1-bit logic signal such that the transistors turned on at the previous time are different from those turned on at the next time.

With reference to one possible implementation manner of the embodiment of the first aspect, the digital low dropout regulator further includes: the selector comprises N-K +1 output ends, the output end of the second controller is connected with the input end of the selector, the control end of the selector is connected with the control end of the second controller, and the first output end of the selector corresponds to 2 corresponding to the K bit signal^K-1 transistor connection, the remaining N-K output terminals of the selector are respectively connected with 2 of the transistors respectively corresponding to the K +1 th bit to the N th bit in the loop control signal^K-1 transistor connection; the method further comprises the following steps:

the second controller is connected by 2 according to the output end of the selector^K-a number of groups N-K +1 of groups of transistors consisting of 1 transistor, generating a selection signal having a bit width N-K +1, said selection signal being used to control said selector to select said 2^K-a target transistor group controlled by a 1-bit logic signal, said target transistor group being any one of N-K +1 transistor groups, each bit of said selection signal controlling one transistor group.

In a third aspect, an embodiment of the present application further provides an electronic device, including: a load and a digital low dropout regulator as provided in the embodiment of the first aspect and/or in connection with any one of the possible implementations of the embodiment of the first aspect, the load being connected to an output of the digital low dropout regulator.

Additional features and advantages of the application will be set forth in the description which follows, and in part will be obvious from the description, or may be learned by the practice of the embodiments of the application. The objectives and other advantages of the application may be realized and attained by the structure particularly pointed out in the written description and drawings.

Drawings

In order to more clearly illustrate the embodiments of the present application or the technical solutions in the prior art, the drawings needed to be used in the embodiments will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the present application, and it is obvious for those skilled in the art to obtain other drawings without creative efforts. The foregoing and other objects, features and advantages of the application will be apparent from the accompanying drawings. Like reference numerals refer to like parts throughout the drawings. The drawings are not intended to be to scale as practical, emphasis instead being placed upon illustrating the subject matter of the present application.

Fig. 1 is a schematic structural diagram of a conventional digital low dropout regulator.

Fig. 2 shows a schematic structural diagram of a digital low dropout regulator according to an embodiment of the present application.

Fig. 3 shows a schematic structural diagram of an extended cycle unit provided in an embodiment of the present application.

Fig. 4 shows a schematic diagram of a cyclic code circuit according to an embodiment of the present application.

Fig. 5 is a schematic structural diagram of another digital low dropout regulator provided in the embodiment of the present application.

Fig. 6 shows a schematic flow chart of a transistor anti-aging method provided by the embodiment of the present application.

Detailed Description

The technical solutions in the embodiments of the present application will be described below with reference to the drawings in the embodiments of the present application.

It should be noted that: like reference numbers and letters refer to like items in the following figures, and thus, once an item is defined in one figure, it need not be further defined and explained in subsequent figures. Meanwhile, relational terms such as "first," "second," and the like may be used solely in the description herein to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus. Without further limitation, an element defined by the phrase "comprising an … …" does not exclude the presence of other identical elements in a process, method, article, or apparatus that comprises the element.

Further, the term "and/or" in the present application is only one kind of association relationship describing the associated object, and means that three kinds of relationships may exist, for example, a and/or B may mean: a exists alone, A and B exist simultaneously, and B exists alone.

As shown in fig. 1, which is a schematic structural diagram of a conventional digital low dropout regulator, in view of the conventional digital low dropout regulator, when a load of the DLDO is in an idle state (idle) or a low power consumption mode, a Loop control signal (Loop data in [ N:1] with a bit width N is output by the DLDO controller]N is a positive integer), only the lower bits (e.g., the lower 3 bits) are changed, and only the transistors with smaller weights are turned on, so that the transistors with smaller weights are always on, and the other transistors are not on when the load is in an idle state or in a low power consumption mode. In the long run, these transistors, which have been in operation, age more quickly and have a reduced lifetime. Wherein the content of the first and second substances,a logic 0 in the loop control signal turns the transistor on and a logic 1 turns the transistor off. When the load is in idle state (idle) or low power mode, assume Loop data in [ N: 1)]If only the lower three bits are changed and the other high bits are all 1, then Loop data in [3: 1]]The minimum is 000 (total of 7 transistors on), the maximum is 111 (no transistor on), and there are eight states. For example, when the bit is 110, the transistor corresponding to the lowest bit (total 2)⁰One) is turned on, and when 101 is obtained, the transistor corresponding to the second bit (2 in total)¹One) is turned on, and when the voltage is 011, the transistor corresponding to the third bit (total 2)²And so on), the number of the transistors which are conducted is adjusted by adjusting the logic value of the lower 3 bits so as to adapt to the current change requirement.

In view of this, the embodiment of the present application provides a digital low dropout regulator, which adds an extended cycle unit, so that when a load is in an idle state (idle) or a low power consumption mode, a transistor corresponding to a few low bits in a loop control signal can be turned on cyclically, thereby preventing the transistor from working for a long time to accelerate aging, and prolonging the service life of the transistor. The digital low dropout regulator provided by the embodiment of the present application will be described with reference to fig. 2. The digital low dropout regulator comprises: a first controller, a transistor array, and an extended circulation unit.

The first controller is configured to generate a Loop control signal (Loop data in [ N:1]) with a bit width N according to a voltage at the voltage output terminal of the DLDO, so as to adjust an output voltage to be stable.

A transistor array comprising 2^N-1 transistor, controlled by a loop control signal, for regulating the output voltage and current by controlling the number of transistors that are turned on by the loop control signal.

The input end of the extended circulation unit is used for receiving signals from the Kth bit to the 1 st bit in the loop control signals (namely, the signals at the input end of the extended circulation unit are the signals from the Kth bit to the 1 st bit in the loop control signals), K is a positive integer and is less than N, and the output end of the extended circulation unit and 2 corresponding to the signals from the Kth bit to the 1 st bit in the transistor array^K-1 transistor connection. Extended cyclic sheetAn element for expanding an input K-bit signal to have i-bit significant bits, and 2^K1 transistors one to one 2^K-a 1-bit logic signal. i is K bit signal and 2^KThe number of transistors respectively currently enabled by the 1-bit logic signal, i.e., the number of transistors respectively currently enabled by the K-bit logic signal, and 2^KThe number of transistors that the-1-bit logic signal can currently turn on respectively is the same. Corresponding to 2 at the previous moment^K-2 of the i-bit significant bits of the 1-bit logic signal corresponding to the subsequent time instant^K-at least one of the i-bit significant bits in the 1-bit logic signal is located differently such that the transistors turned on at a previous time are different from those turned on at a subsequent time, i is 0 or more and 2 or less^KAn integer of-1, i.e., i is an integer, and 0. ltoreq. i.ltoreq.2^K-1. Therein, 2^K-one bit of the 1-bit logic signal and 2^KOne transistor of 1 transistor corresponds, and the transistors corresponding to different bits differ.

For convenience of understanding, for example, if K is 3, the extended loop unit extends an input 3-bit signal into a 7-bit logic signal output having i-bit valid bits; if K equals 4, the expanding circulation unit expands the input 4-bit signal into a 15-bit logic signal output with i-bit valid bits, and so on. The number of transistors of the K bit signal which can be switched on currently is 2^KThe number of transistors that the 1-bit logic signal can currently turn on is the same, i, e.g., 2 if the K-bit signal is 000^K-1 bit logic signal is also 0000000, and if K bit signal is 111, 2^KThe logic signal of-1 bit is also 1111111, if the K bit signal is 011, it is only necessary to ensure that the 7 bit logic signal has 4 bits of valid bits (logic 0) without paying attention to the positions of the 4 bits, and the positions of at least one bit of the 4 bits of valid bits at the previous time and the later time are different, so that the transistors turned on at the previous time and the later time are different, for example, clk1 (time 1), the corresponding logic signals of 7 bits are 0000111, clk2 (time 2), the corresponding logic signals of 7 bits are 1000011, clk3 (time 3), the corresponding logic signals of 7 bits are 1100001, clk4 (time 4), the corresponding logic signals of 7 bits are 1110000, clk5 (time 5), and the corresponding logic signals of 7 bits are 11000010111000, clk6 (time 6), corresponding 7-bit logic signals 0011100, clk7 (time 7), corresponding 7-bit logic signals 0001110, clk8 (time 8), corresponding 7-bit logic signals 0000111 … …. Therefore, the originally fixed conducting transistor can be circulated among the seven power tubes and is not in fixed conduction any more, and the aging time of the fixed power tubes is prolonged. Further, if the K bit signal is 011, only 4-7 transistors numbered 1-7 can be turned on, and any 4 transistors numbered 1-7 among the 7 transistors can be turned on by the method of the present application, so that the 4-7 transistors do not work for a long time any more, and the aging time is prolonged.

It is noted that, in addition to periodically adjusting 2 in a particular order according to the above example^KIn addition to the position of the i-bit significant bit in the 1-bit logic signal, 2 can also be randomly adjusted^K-the position of the i-bit valid bit in the 1-bit logic signal, provided that it is ensured that at least one of the i-bit valid bits differs from the position of at least one of the i-bit valid bits at the previous time and at the subsequent time. clk1 (time 1), corresponding 7-bit logic signals 0000111, clk2 (time 2), corresponding 7-bit logic signals 0111000, clk3 (time 3), and corresponding 7-bit logic signals 0110001 … ….

The extended cycle unit may implement the above functions in a hardware-based manner, or may implement the above functions in a software-based manner. When the extended loop unit implements the above functions in a software-based manner, the extended loop unit may be a second controller in which a specific program is fixed. The specific program is used for determining the number i of transistors which can be switched on currently by the K bit signal according to the input K bit signal when being operated by the second controller; and expanding the input K bit signal into 2 with i bit effective bit according to the transistor conducting number i^KA 1-bit logic signal, of which 2^K-one bit of the 1-bit logic signal and 2^K-one transistor of 1 transistor corresponds; and also for periodically or randomly adjusting 2^K-the position of the i-bit valid bit in the 1-bit logic signal, such that the previous time corresponds to 2^K-2 of the i-bit significant bits of the 1-bit logic signal corresponding to the subsequent time instant^KAt least one of the i-bit active bits in the 1-bit logic signal is located differently, so that the transistors turned on at the previous time are different from those turned on at the next time.

Wherein the second controller may be an integrated circuit chip having signal processing capability. The second controller may be a general-purpose Processor, including a Central Processing Unit (CPU), a Network Processor (NP), and the like; but also Digital Signal Processors (DSPs), Application Specific Integrated Circuits (ASICs), Field Programmable Gate Arrays (FPGAs) or other Programmable logic devices, discrete Gate or transistor logic devices, discrete hardware components. The various methods, steps, and logic blocks disclosed in the embodiments of the present application may be implemented or performed. The general purpose processor may be a microprocessor or the second controller may be any conventional processor or the like.

It should be noted that, the first controller and the second controller may be two independent controllers, or may refer to the same controller, and in this embodiment, the digital low dropout regulator has only one controller.

When the extended loop unit implements the above functions in a hardware-based manner, in one embodiment, as shown in fig. 3, the extended loop unit includes: thermometer decoder and cyclic code circuit. The thermometer decoder has input end for receiving the K-th to 1-th bit signals in the loop control signal, output end connected to the cyclic code circuit, and output end for decoding the input K-bit signals into 2 with i-bit effective bits^K-a 1-bit logic signal. Cyclic code circuit and 2 corresponding to K bit signal in transistor array^K-1 transistor connected, cyclic code circuit for adjusting 2 in a specific order^K-the position of the i-bit valid bit in the 1-bit logic signal.

In one embodiment, a schematic diagram of a cyclic code circuit may be shown in fig. 4. The cyclic code circuit includes: 2^K-1 and gate and 2^K1 Flip-Flop (D Flip Flop, DFF). 2^K-one bit of the 1-bit logic signal and 2^K-one and gate of the 1 and gates, each and gate corresponding to a unique flip-flop, each flip-flop corresponding to a unique transistor. For each AND gate, the first input terminal of the AND gate is connected to 2^K-a corresponding bit of the 1-bit logic signal is connected, a second input of the and-gate is externally connected with a setting signal (setting), and an output of the and-gate is connected with a corresponding flip-flop. 2^K-1 flip-flops connected in series to form a flip-flop chain, i.e. the output (Q) of the first flip-flop is connected to the input (D) of the second flip-flop, and the output (Q) of the second flip-flop is connected … … to the input (D) of the third flip-flop^K-2 flip-flop outputs (Q) and 2 nd^K-the inputs (D) of 1 flip-flop are connected. In addition, the input end (D) of the trigger at the head end of the trigger chain is also connected with the output end (Q) of the trigger at the tail end of the trigger chain so as to realize circulation. For each flip-flop, the set terminal (set) of the flip-flop is connected to the output terminal of the corresponding and gate, the reset terminal (reset) of the flip-flop is grounded, and the output terminal (Q) of the flip-flop is also connected to the corresponding transistor. At the beginning, setting the setting signal (setting) to 1 (high level), and after the setting signal is compared with the output phase of the thermometer decoder, outputting the output phase to the setting end (set) of the trigger to set the initial value of the trigger, and then setting the setting signal (setting) to 0 (high level) to make the setting ends of all the triggers to be 0, so that the original data is kept to circulate in the trigger chain. The relationship between the set terminal (set) and the reset terminal (reset) of the flip-flop and the initial value is shown in table 1.

TABLE 1

Setting terminal (set)	Reset terminal (reset)	Initial value
			1	0	1
0	1	0
			0	0	Holding
1	1	Are not allowed to be 1 at the same time

The circuit diagram shown in fig. 4 is only one embodiment of a cyclic code circuit, and therefore, it is not to be understood that the cyclic code circuit is specifically limited, for example, in one embodiment, the and gate in fig. 4 may be replaced by a nand gate and a nor gate, and another cyclic code circuit is formed.

When the extended loop unit implements the above functions in a hardware-based manner, in another embodiment, the extended loop unit includes: a thermometer decoder and a random number generator. The thermometer decoder has input end for receiving the K-th to 1-th bit signals in the loop control signal, output end connected to the random number generator, and output end for decoding the input K-bit signals into 2 with i-bit effective bits^K-a 1-bit logic signal. Random number generator, 2 corresponding to K bit signal in transistor array^K-1 transistor connection, random number generator for 2 according to input^K-the number i of significant bits in the 1-bit logic signal and the total number (2)^K-1 bit) periodically randomly generating the same total number of bits and the significant number of bitsIs 2 of i^KLogic signal of 1 bit, thus realizing random adjustment 2 periodically^K-the position of the i-bit valid bit in the 1-bit logic signal. For example, the 7-bit logic signals input to the random number generator are 0000111 and clk1 (time 1), the 7-bit logic signals output by the random number generator are 1000110 and clk2 (time 2), the 7-bit logic signals output by the random number generator are 0111000 and clk3 (time 3), and the 7-bit logic signals output by the random number generator are 0110001 … ….

In addition, when the load of DLDO is in idle state (idle) or low power mode, except that the transistor which is turned on is at 2 corresponding to the K bit signal^KBesides cycling between-1 transistor, cycling can also be performed in the transistors corresponding to the K +1 th bit to the Nth bit. When the load of the DLDO is in an idle state (idle) or a low power consumption mode, only K-bit signals in N-bit Loop control signals are changed, the K +1 th bit to the N-th bit are all 1, and corresponding transistors are all closed, so that the load of the DLDO can be controlled from the Loop data in [ N: K + 1]]One transistor group (2) is taken out from each transistor controlled by each bit^K-1), i.e. the transistor corresponding to the K +1 th bit signal (total 2)^K2) is taken out^K1 transistor corresponding to the K +2 bit signal (total 2)^K+12) is taken out^K-1 transistor … … from the transistor corresponding to the Nth bit signal (total of 2)^N-12) is taken out^K1 transistor with N-K groups, plus 2 for the K bit signal^K-1 transistor with a total of N-K +1 transistors of 2^K-a transistor group formed by 1 transistor. Using a selector to select a specific controlled transistor group (target transistor group), again according to 2^K-1 bit logic signal to effect the cycling of the conducting transistor in the selected target transistor group. At this time, the digital low dropout regulator further includes: a selector.

As shown in fig. 5, the selector includes N-K +1 output terminals, the output terminal of the extended cyclic unit is connected to the input terminal of the selector, the control terminal of the selector is connected to a selection signal (bit width is N-K +1, each bit controls a transistor group), and the first output terminal of the selector is connected to 2 corresponding to the K bit signal^K-1 transistor connection, selector remainingN-K output ends respectively correspond to 2 of transistors from the K +1 th bit to the N th bit in the loop control signal^K-1 transistor connection.

A selector for selecting 2 according to the selection signal^K-a set of target transistors controlled by a 1-bit logic signal, the set of target transistors being N-K +1 and 2^K-any of the group of 1 transistor. Specifically, the transistor group corresponding to the effective bit position is selected to operate according to the position of the effective bit in the selection signal. For the sake of easy understanding, the logic 1 is used to represent an effective example, assuming that N-K +1 is 5, if the selection signal is 00001, the target transistor group is 2 corresponding to the K-bit signal^K-a transistor group of 1 transistor, and if the selection signal is 00010, the target transistor group is a 2 bit corresponding to the K +1 bit signal^KA transistor group consisting of 1 transistor, and if the selection signal is 10000, the target transistor group is 2 corresponding to the K +4 th bit (i.e. the N bit) signal^K-a transistor group of 1 transistor. By selecting the position of the effective bit in the signal, the target transistor group selected by the selector can be N-K +1 and 2^K-any one of a group of 1 transistor.

The selection signal may be output by the first controller, or may be output by the second controller.

In addition, a group of 2-bit transistors can be taken out from the transistors corresponding to the K + 1-bit to the N-bit^KBesides the group of transistors of-1 transistor, it can also be a group of transistors from which part of the group of transistors is taken out, for example, assuming Loop data in [ N: K + 1]]Is Loop data in [7:4 ]]Then, 1, 2 or 3 sets of the 4 sets (one set of the 4 th to 7 th transistors, 4 sets) may be used to match the Loop data in [3: 1]]The corresponding transistor groups together constitute a candidate transistor group for the selector. For the sake of understanding, taking any one group from N-K as an example, in this case, the output terminal of the extended cyclic unit is connected to the input terminal of the selector, and the first output terminal of the selector is connected to 2 corresponding to the K-bit signal^K-1 transistor connection; second output terminal of the selector and the y-th bit in the loop control signalCorresponding to 2^y-12 of one transistor^K-1 transistor connected, y being an integer greater than or equal to K +1 and less than or equal to N, i.e. y is an integer, and K + 1. ltoreq. y.ltoreq.N. The control terminal of the selector is connected with a selection signal, and the selector is used for selecting 2 according to the selection signal^K-1 bit logic signal is 2 corresponding to control K bit signal^K-1 transistor or 2 for the y-th bit^K-1 transistor. In this embodiment, the number of bits of the selection signal may be 1, for example, if the bit is logic 0, the selector is used to select 2^K-1-bit logic signal controlling the corresponding 2 of K-bit signal^K-1 transistor active, if the bit is a logic 1, the selector is used to select 2^K-1 bit logic signal controlling the corresponding 2 of the y bit^KThe-1 transistor operates, but of course the reverse is possible.

The embodiment of the present application further provides a transistor anti-aging method applied to the digital low dropout regulator, and the transistor anti-aging method provided by the embodiment of the present application will be described below with reference to fig. 6. Wherein, digital low dropout regulator includes: the device comprises a transistor array, a first controller and a second controller; the first controller is used for generating a loop control signal, the bit width of the loop control signal is N, and N is a positive integer; the input end of the second controller is used for receiving signals from the Kth bit to the 1 st bit in the loop control signals, K is a positive integer and is less than N, and the output end of the second controller and the 2 nd bit corresponding to the K bit signals in the transistor array^K-1 transistor connection.

Step S101: the second controller determines the number i of transistors which can be switched on currently by the K bit signal according to the input K bit signal.

Wherein i is not less than 0 and not more than 2^K-an integer of 1.

Step S102: the second controller expands the input K bit signal into 2 with i bit valid bit according to the transistor conducting number i^K-a 1-bit logic signal.

Therein, 2^K-1 bit logic signal and said 2^K1 transistors one to one, i.e. 2^K-one bit of the 1-bit logic signal and said 2^KOne transistor of 1 transistor corresponds and the transistors corresponding to different bits are different.

Step S103: the second controller adjusts the 2 periodically or randomly^K-the position of the i-bit active bit in the 1-bit logic signal such that the transistors turned on at the previous time are different from those turned on at the next time.

Optionally, the digital low dropout regulator further comprises: the selector comprises N-K +1 output ends, the output end of the second controller is connected with the input end of the selector, the control end of the selector is connected with the control end of the second controller, and the first output end of the selector corresponds to 2 corresponding to the K bit signal^K-1 transistor connection, the remaining N-K output terminals of the selector are respectively connected with 2 of the transistors respectively corresponding to the K +1 th bit to the N th bit in the loop control signal^K-1 transistor connection. At this time, the method further includes: the second controller is connected by 2 according to the output end of the selector^K-a number of groups N-K +1 of groups of transistors consisting of 1 transistor, generating a selection signal having a bit width N-K +1, said selection signal being used to control said selector to select said 2^K-a target transistor group controlled by a 1-bit logic signal, said target transistor group being any one of N-K +1 transistor groups, each bit of said selection signal controlling one transistor group.

The method provided by the embodiment of the present application, which has the same implementation principle and the same technical effect as the foregoing device embodiment, for the sake of brief description, and where no part of the method embodiment is mentioned, reference may be made to the corresponding content in the foregoing device embodiment.

The embodiment of the application also provides an electronic device, which comprises a load and the digital low dropout regulator. The load may be a processor, a memory, or other devices that need to be powered by the digital LDO.

The electronic device includes, but is not limited to, a computer, a tablet computer, a smart phone, a server, and the like.

The electronic device provided in the embodiment of the present application has the same implementation principle and technical effect as those of the digital low dropout regulator embodiment, and for brief description, reference may be made to the corresponding contents in the digital low dropout regulator embodiment for a part of the embodiments of the electronic device that are not mentioned.

It should be noted that, in the present specification, the embodiments are all described in a progressive manner, each embodiment focuses on differences from other embodiments, and the same and similar parts among the embodiments may be referred to each other.

The above description is only for the specific embodiments of the present application, but the scope of the present application is not limited thereto, and any person skilled in the art can easily conceive of the changes or substitutions within the technical scope of the present application, and shall be covered by the scope of the present application. Therefore, the protection scope of the present application shall be subject to the protection scope of the claims.

Claims

1. A digital low dropout voltage regulator, comprising:

an array of transistors;

the first controller is used for generating a loop control signal, the bit width of the loop control signal is N, and N is a positive integer;

an input end of the extended circulation unit is used for receiving K bit to 1 bit signals in the loop control signals, and an output end of the extended circulation unit is connected with 2 bits corresponding to the K bit signals in the transistor array^K-1 transistor connection, K being a positive integer and less than N;

the extended cyclic unit for extending the input K-bit signal to have i-bit significant bits and to be compared with the 2 bits^K1 transistors one to one 2^K-1 bit logic signal, i is an integer and 0 ≦ i ≦ 2^K-1；

Wherein i is the K bit signal and the 2^KThe number of transistors that the 1-bit logic signal can be switched on at present, respectively, and 2 at the previous moment^K-2 of the i-bit significant bits of the 1-bit logic signal corresponding to the subsequent time instant^K-at least one of the i-bit active bits in the 1-bit logic signal is located differently such that the transistors turned on at the previous time are different from the transistors turned on at the subsequent time.

2. The digital LDO of claim 1, further comprising:

the output end of the extended cycle unit is connected with the input end of the selector, and the first output end of the selector is connected with 2 corresponding to the K bit signal^K-1 transistor connection, the second output of the selector corresponding to 2 of the y-th bit in the loop control signal^y-12 of one transistor^K-1 transistor, the control terminal of the selector being connected to a selection signal, y being an integer, and K +1 ≦ y ≦ N;

the selector is used for selecting the 2 according to the selection signal^K-1-bit logic signal is 2 for controlling said K-bit signal^K-1 transistor or 2 for the y-th bit^K-1 transistor.

3. The digital LDO of claim 1, further comprising:

the selector comprises N-K +1 output ends, the output end of the extended circulation unit is connected with the input end of the selector, the control end of the selector is connected with a selection signal, and the first output end of the selector corresponds to 2 corresponding to the K bit signal^K-1 transistor connection, the remaining N-K output terminals of the selector are respectively connected with 2 of the transistors respectively corresponding to the K +1 th bit to the N th bit in the loop control signal^K-1 transistor connection;

the selector is used for selecting the 2 according to the selection signal^K-a set of target transistors controlled by a 1-bit logic signal, said set of target transistors being N-K +1 and 2^K-any one of a group of 1 transistors, wherein the bit width of the selection signal is N-K +1, each bit controlling one transistorA tube set.

4. The digital LDO of claim 1, wherein said extended cycle unit comprises:

a thermometer decoder, the input end of the thermometer decoder is used for receiving the K bit to 1 bit signals in the loop control signals, the output end of the thermometer decoder is connected with the cyclic code circuit, the thermometer decoder is used for decoding the input K bit signals into 2 bits with i bit effective bits^K-a 1-bit logic signal;

the cyclic code circuit corresponds to 2 of the transistor array corresponding to the K-bit signal^K-1 transistor connection, said cyclic code circuit for adjusting said 2 in a specific order^K-the position of the i-bit valid bit in the 1-bit logic signal.

5. The digital low dropout regulator of claim 4, wherein said cyclic code circuit comprises:

2^K-1 and gates, said 2^K-1 bit logic signal and said 2^K-1 and gates in one-to-one correspondence; for each AND gate, the first input terminal of the AND gate is connected to the 2^K-a corresponding bit of the 1-bit logic signal is connected, a second input terminal of the and gate is externally connected with a setting signal, and an output terminal of the and gate is connected with a corresponding flip-flop;

and said 2^K1 AND gates one to one 2^K-1 flip-flop, said 2^K-1 flip-flop with said 2^K-1 transistor to one; 2 is described^K-1 flip-flops are connected in series to form a flip-flop chain; the input end of the trigger positioned at the head end of the trigger chain is also connected with the output end of the trigger positioned at the tail end of the trigger chain; for each trigger, the setting end of the trigger is connected with the output end of the corresponding AND gate, the reset end of the trigger is grounded, and the output end of the trigger is also connected with the corresponding transistor.

6. The digital LDO of claim 1, wherein said extended cycle unit comprises:

a thermometer decoder, an input end of the thermometer decoder is used for receiving K bit to 1 bit signals in the loop control signals, an output end of the thermometer decoder is connected with the random number generator, and the thermometer decoder is used for decoding the input K bit signals into 2 bits with i bit significant bits^K-a 1-bit logic signal;

the random number generator is 2 corresponding to the K bit signal in the transistor array^K-1 transistor connection, said random number generator for periodically randomly adjusting said 2^K-the position of the i-bit valid bit in the 1-bit logic signal.

7. The digital LDO of claim 1, wherein said extended cycle unit is a second controller with a specific program fixed;

the specific program is used for determining the number i of transistors which can be switched on currently according to the input K bit signal when being operated by the second controller; and expanding the input K bit signal into 2 with i bit effective bit according to the transistor conducting number i^K-a 1-bit logic signal; and also for periodically or randomly adjusting said 2^K-the position of the i-bit active bit in the 1-bit logic signal such that the transistors turned on at the previous time are different from those turned on at the next time.

8. A transistor anti-aging method is applied to a digital low dropout regulator, and the digital low dropout regulator comprises the following steps: the device comprises a transistor array, a first controller and a second controller; the first controller is used for generating a loop control signal, the bit width of the loop control signal is N, and N is a positive integer; the input end of the second controller is used for receiving signals from the Kth bit to the 1 st bit in the loop control signals, K is a positive integer and is less than N, and the output end of the second controller and the 2 nd bit corresponding to the K bit signals in the transistor array^K-1 transistor connection; the method comprises the following steps:

the second controller determines the number i of transistors which can be switched on currently by the K bit signal according to the input K bit signal, wherein i is more than or equal to 0 and less than or equal to 2^K-an integer of 1;

the second controller expands the input K bit signal into 2 with i bit valid bit according to the transistor conducting number i^K-a 1-bit logic signal, wherein said 2^K-1 bit logic signal and said 2^K-1 transistor to one;

the second controller adjusts the 2 periodically or randomly^K-the position of the i-bit active bit in the 1-bit logic signal such that the transistors turned on at the previous time are different from those turned on at the next time.

9. The method of claim 8, wherein the digital low dropout regulator further comprises: the selector comprises N-K +1 output ends, the output end of the second controller is connected with the input end of the selector, the control end of the selector is connected with the control end of the second controller, and the first output end of the selector corresponds to 2 corresponding to the K bit signal^K-1 transistor connection, the remaining N-K output terminals of the selector are respectively connected with 2 of the transistors respectively corresponding to the K +1 th bit to the N th bit in the loop control signal^K-1 transistor connection; the method further comprises the following steps:

10. An electronic device, comprising: a load and a digital low dropout regulator according to any one of claims 1 to 7, the load being connected to an output of the digital low dropout regulator.